Your search keyword '"Cabrales, Pedro"' showing total 40 results

1. Improving cardiac function with new-generation plasma volume expanders.

Author

Chatpun S, Nacharaju P, and Cabrales P

Subjects

Analysis of Variance, Animals, Cardiac Catheterization, Cricetinae, Male, Mesocricetus, Resuscitation methods, Vascular Resistance drug effects, Blood Volume drug effects, Cardiac Output drug effects, Hemodilution methods, Plasma Substitutes pharmacology, Polyethylene Glycols pharmacology, Serum Albumin pharmacology, Shock, Hemorrhagic drug therapy, Ventricular Function, Left drug effects

Abstract

Background: Plasma expander (PE) based on polyethylene glycol (PEG) conjugated to albumin has shown positive results maintaining blood volume during hemodilution and restoring blood volume during resuscitation from hemorrhagic shock. Polyethylene glycol conjugation to human serum albumin (HSA), PEG-HSA, increases size, weight, and colloidal osmotic pressure, with minor effects on solution viscosity., Methods: This study was designed to test the hypothesis that PEG-HSA (2 g/dL) produced by direct PEGylation chemistry improves cardiac function during 2 experimental models, (i) moderate hemodilution and (ii) resuscitation from hemorrhagic shock, compared with a conventional colloidal PE (Dextran 70 kd [Dx70], 6 g/dL). Cardiac function was studied using a miniaturized pressure volume conductance catheter implanted in the left ventricle and evaluated in terms of cardiac indices derived from the pressure volume measurements., Results: Polyethylene glycol-HSA increased cardiac output, stroke volume, and stroke work and decreased systemic vascular resistance compared with Dx70 in both experimental models. The improvements induced by PEG-HSA in cardiac function were sustained over the observation time. Polyethylene glycol-HSA cardiac mechanoenergetics changes are the result of increased energy transferred per stroke and decreased resistance of the vasculature connecting the heart. In summary, PEG-HSA decreased left ventricle ejection impedance., Conclusion: Ejection of blood diluted with PEG-HSA presented a reduced load to the heart, increased contractile function, and lowered the energy consumed per unit volume compared with Dx70. Our results emphasize the importance of heart function as a parameter to be included in the evaluation changes induced by new PEs., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

2. Exogenous intravascular nitric oxide enhances ventricular function after hemodilution with plasma expander.

Author

Chatpun S and Cabrales P

Subjects

Animals, Blood Volume drug effects, Blood Volume physiology, Cricetinae, Hemodilution adverse effects, Infusions, Intra-Arterial, Infusions, Intravenous, Male, Mesocricetus, Nitric Oxide Donors administration & dosage, Plasma Substitutes adverse effects, Ventricular Function, Left physiology, Hemodilution methods, Nitric Oxide administration & dosage, Plasma Substitutes administration & dosage, Ventricular Function, Left drug effects

Abstract

Aims: This study evaluated the hypothesis that exogenous nitric oxide (NO) supplementation during acute hemodilution with plasma expander (PE) provides beneficial effects on cardiac function., Main Methods: Acute hemodilution in golden Syrian hamsters was induced by a 40% of blood volume exchange with dextran 70 kDa. Intravascular NO supplementation after hemodilution was accomplished with a NO donor, diethylenetriamine NONOate (DETA NONOate). The test group was treated with DETA NONOate, while the control group received only vehicle. Left ventricular cardiac function was studied using pressure-volume measurements obtained with a miniaturized conductance catheter., Key Findings: Cardiac output increased to 122±5% and 107±1% of the baseline in the group treated with NO donor and the vehicle group, respectively. Stroke work per stroke volume (SW/SV) after hemodilution reduced to 90% of the baseline and the NO donor significantly reduced SW/SV compared to the vehicle. The minimum rate of pressure change (dP/dt(min)) was significantly lower in animals treated with the NO donor compared to vehicle treated animals. Systemic vascular resistance (SVR) decreased to 62±5% of the baseline in the NO donor group whereas the vehicle group SVR decreased to 83±5% of the baseline. Using intravital microscopy analysis of microvessel in the dorsal skinfold window chamber, we established that the NO donor group induced significant vasodilation compared to the vehicle group., Significance: NO supplementation in an acute hemodilution with PE has beneficial effects on cardiac performance. However, the NO supplementation effects with a NO donor are dose-independent and short-lasting., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2012

3. Plasma expander viscosity effects on red cell-free layer thickness after moderate hemodilution.

Author

Yalcin O, Wang Q, Johnson PC, Palmer AF, and Cabrales P

Subjects

Animals, Blood Flow Velocity, Endothelium, Vascular physiology, Erythrocytes physiology, Glutaral chemistry, Hematocrit, Humans, Polymerization, Rats, Rats, Sprague-Dawley, Serum Albumin chemistry, Shear Strength, Blood Viscosity physiology, Hemodilution

Abstract

The objective of the study was to investigate the effects of plasma viscosity after hemodilution on the thickness of the erythrocyte cell free layer (CFL) and on the interface between the flowing column of erythrocytes and the vascular endothelium. The erythrocyte CFL thickness was measured in the rat cremaster muscle preparation. Plasma viscosity was modified in an isovolemic hemodilution, in which the systemic hematocrit (Hctsys) was lowered to 30%. The plasma expanders (PE) of similar nature and different viscosities were generated by glutaraldehyde polymerization of human serum albumin (HSA) at various molar ratios glutaraldehyde to HSA: (i) unpolymerized HSA; (ii) PolyHSA24:1, molar ratio = 24 and (iii) PolyHSA60:1, molar ratio = 60. The HSA viscosities determined at 200 s(-1) were 1.1, 4.2 and 6.0 dyn x cm(-2), respectively. CFL thickness, vessel diameter and blood flow velocity were measured, while volumetric flow, shear rate and stress were calculated. Hemodilution with PolyHSA60:1 increased plasma viscosity and the blood showed marked shear thinning behavior. CFL thickness decreased as plasma viscosity increased after hemodilution; thus the CFL thickness with HSA and PolyHSA24:1 increased compared to baseline. Conversely, the CFL thickness of PolyHSA60:1 was not different from baseline. Blood flow increased with both PolyHSA's compared to baseline. Wall shear rate and shear stress increased for PolyHSA60:1 compared to HSA and PolyHSA24:1, respectively. In conclusion, PE viscosity determined plasma viscosity after hemodilution and affected erythrocyte column hydrodynamics, changing the velocity profile, CFL thickness, and wall shear stress. This study relates the perfusion caused by PolyHSA60:1 to hemodynamic changes induced by the rheological properties of blood diluted with PolyHSA60:1.

Published

2011

4. Tissue oxidative metabolism after extreme hemodilution with PEG-conjugated hemoglobin.

Author

Cabrales P, Meng F, and Acharya SA

Subjects

Acid-Base Equilibrium drug effects, Anemia blood, Anemia physiopathology, Animals, Connective Tissue blood supply, Connective Tissue metabolism, Cricetinae, Fluorometry, Hemodynamics drug effects, Hypoxia blood, Hypoxia physiopathology, Male, Mesocricetus, Microcirculation drug effects, Muscles blood supply, Muscles metabolism, NAD metabolism, Time Factors, Anemia chemically induced, Blood Substitutes toxicity, Connective Tissue drug effects, Hemodilution adverse effects, Hemoglobins toxicity, Hypoxia chemically induced, Maleimides toxicity, Muscles drug effects, Oxygen blood, Polyethylene Glycols toxicity

Abstract

NADH-localized fluorometry was used as a noninvasive technique to monitor changes in the energy state of intact tissue (muscle and connective tissue), without anesthesia, as a function of blood plasma O(2)-carrying capacity in the hamster window chamber model. Acute moderate isovolemic hemodilution was induced by two isovolemic hemodilution steps: in the first step, 6% 70-kDa dextran (Dex70) was used to induce an acute anemic state (18% Hct); in the second step, exchange transfusion of polyethylene glycol (PEG) maleimide-conjugated Hb (4 g/dl, PEG-Hb) or Dex70 (6 g/dl) was used to reduce erythrocytes to 75% of baseline (11% Hct). PEG-Hb had six copies of PEG (5 kDa) conjugated to each human Hb (0.48 g PEG/g Hb) through extension arm-facilitated chemistry. Systemic parameters, microvascular perfusion, functional capillary density, intravascular and interstitial Po(2), and intracellular NADH fluorescence were monitored. Mean arterial blood pressure after extreme hemodilution was statistically significantly reduced for Dex70 compared with PEG-Hb. The presence of PEG-Hb in the circulation maintained positive acid-base balance. While microvascular blood flows were not different, functional capillary density was significantly higher for PEG-Hb than Dex70. Arteriolar Po(2) was higher in the presence of PEG-Hb than Dex70, but tissue and venular Po(2) were not different. Cellular energy metabolism (intracellular O(2)) in the tissues was improved with PEG-Hb. Moderate hemodilution to 18% Hct (6.4 g Hb/dl) brings tissue O(2) delivery to the verge of inadequacy. Extreme hemodilution to 11% Hct (3.7 g Hb/dl) produces tissue anoxia, and high-O(2)-affinity PEG-Hb (Po(2) at which blood is 50% saturated with O(2) = 4 Torr, 1.1 g Hb/dl) only partially decreases anaerobic metabolism without increasing tissue Po(2).

Published

2010

5. The variability of blood pressure due to small changes of hematocrit.

Author

Vázquez BY, Martini J, Tsai AG, Johnson PC, Cabrales P, and Intaglietta M

Subjects

Animals, Blood Viscosity physiology, Blood Volume physiology, Cricetinae, Mesocricetus, Anemia physiopathology, Blood Pressure physiology, Hematocrit, Hemodilution, Hemodynamics physiology

Abstract

The hematocrit (Hct) of awake hamsters was lowered to 90% of baseline by isovolemic hemodilution using hamster plasma to determine the acute effect of small changes in Hct and blood viscosity on systemic hemodynamics. Mean arterial blood pressure increased, reaching a maximum of about 10% above baseline (8.6 +/- 5.5 mmHg) when Hct decreased 8.4 +/- 1.9% (P < 0.005). Cardiac output increased continuously with hemodilution. These conditions were reached at approximately 60 min after exchange transfusion and remained stationary for 1 h. Peripheral vascular resistance was approximately constant up to a decrease of Hct of about 10% and then fell continuously with lowering Hct. Vascular hindrance or vascular resistance independent of blood viscosity increased by about 20% and remained at this level up to an Hct decrease of 20%, indicating that the vasculature constricted with the lowered Hct. The results for the initial 2-h period are opposite but continuous with previous findings with small increases in Hct. In conclusion, limited acute anemic conditions increase mean arterial blood pressure during the initial period of 2 h, an effect that is quantitatively similar but opposite to the acute increase of Hct during the same period.

Published

2010

6. Cardiac mechanoenergetic cost of elevated plasma viscosity after moderate hemodilution.

Author

Chatpun S and Cabrales P

Subjects

Animals, Biomechanical Phenomena physiology, Blood Pressure physiology, Cricetinae, Heart Rate physiology, Male, Stress, Mechanical, Stroke Volume, Systole physiology, Vascular Resistance physiology, Blood Viscosity physiology, Heart physiology, Hemodilution

Abstract

The purpose of this study was to investigate how plasma viscosity affects cardiac and vascular function during moderate hemodilution. Twelve anesthetized hamsters were hemodiluted by 40% of blood volume with two different viscosity plasma expanders. Experimental groups were based on the plasma expander viscosity, namely: high viscosity plasma expander (HVPE, 6.3 mPa · s) and low viscosity plasma expander (LVPE, 2.2 mPa · s). Left ventricular (LV) function was intracardiacally measured with a high temporal resolution miniaturized conductance catheter and concurrent pressure-volume results were used to calculate different LV indices. Independently of the plasma expander, hemodilution decreased hematocrit to 28% in both groups. LVPE hemodilution reduced whole blood viscosity by 40% without changing plasma viscosity, while HVPE hemodilution reduced whole blood viscosity by 23% and almost doubled plasma viscosity relative to baseline. High viscosity plasma expander hemodilution significantly increased cardiac output, stroke volume and stroke work compared to baseline, whereas LVPE hemodilution did not. Furthermore, an increase in plasma viscosity during moderate hemodilution produced a higher energy transfer per unit volume of ejected blood. Systemic vascular resistance decreased after hemodilution in both groups. Counter-intuitively, HVPE hemodilution showed lower vascular resistance and vascular hindrance than LVPE hemodilution. This result suggests that geometrical changes in the circulatory system are induced by the increase in plasma viscosity. In conclusion, an increase in plasma viscosity after moderate hemodilution directly influenced cardiac and vascular function by maintaining hydraulic power and reducing systemic vascular resistance through vasodilation.

Published

2010

7. Oxygen transport during hemodilution with a perfluorocarbon-based oxygen carrier: effect of altitude and hyperoxia.

Author

Gardeazábal T, Cabrera M, Cabrales P, Intaglietta M, and Briceño JC

Subjects

Animals, Biological Transport, Active, Blood Gas Analysis, Emulsions, Hematocrit, Hemoglobins metabolism, Male, Rats, Rats, Sprague-Dawley, Altitude, Blood Substitutes pharmacology, Fluorocarbons pharmacology, Hemodilution, Hyperoxia metabolism, Oxygen blood

Abstract

Oxygen delivery and consumption after hemodilution with a perfluorocarbon-based oxygen carrier (PFCOC) was evaluated at sea level and at 2,600 m above sea level. Fifteen anesthetized rats were subjected to a two-exchange normovolemic hemodilution of 40% of the circulating blood volume each. First exchange was performed with a colloid solution. Second exchange was with 80% PFCOC and 20% colloid. Animals were then ventilated with 100% oxygen. Experiments were performed at barometric pressure of 1.0 atm (sea-level group, n=9) or 0.74 atm (2,600-m group, n=6). Blood gases, hematocrit, fluorocrit, and hemoglobin content were measured at baseline and 15 min after each exchange. After hemodilution, total arterial content was not modified by the PFCOC in either group. In contrast, arteriovenous oxygen difference increased significantly in both groups, as did the oxygen extraction ratio. In the second exchange, although total arterial content was similar between the two groups, the perfluorocarbon and plasma phases contributed significantly more at sea level. Arteriovenous oxygen difference was significantly less at sea level with a higher contribution from the perfluorocarbon and plasma phases. In conclusion, hemodilution with a PFCOC induced changes in oxygen delivery and consumption that differ with altitude. The 2,600-m group exhibited a higher oxygen extraction ratio and arteriovenous oxygen difference, with reduced oxygen delivery and unloading from both the fluorocarbon and plasma phase. Therefore, the efficacy of PFCOCs at 2,600 m above sea level is reduced, and altitude must be taken into account when PFCOCs are used.

Published

2008

8. Survival time in severe hemorrhagic shock after perioperative hemodilution is longer with PEG-conjugated human serum albumin than with HES 130/0.4: a microvascular perspective.

Author

Martini J, Cabrales P, K A, Acharya SA, Intaglietta M, and Tsai AG

Subjects

Albumins administration & dosage, Analysis of Variance, Animals, Blood Loss, Surgical prevention & control, Blood Viscosity drug effects, Cricetinae, Hemodynamics drug effects, Hydroxyethyl Starch Derivatives administration & dosage, Male, Microcirculation, Plasma Substitutes administration & dosage, Polyethylene Glycols administration & dosage, Statistics, Nonparametric, Survival Analysis, Albumins pharmacology, Hemodilution methods, Hydroxyethyl Starch Derivatives pharmacology, Plasma Substitutes pharmacology, Polyethylene Glycols pharmacology, Shock, Hemorrhagic physiopathology

Abstract

Introduction: Preoperative hemodilution is an established practice that is applied to reduce surgical blood loss. It has been proposed that polyethylene glycol (PEG) surface decorated proteins such as PEG-conjugated human serum albumin may be used as non-oxygen-carrying plasma expanders. The purpose of this study was to determine whether there is any difference in survival time after severe hemorrhagic shock following extreme hemodilution using a conventional hydroxyethyl starch (HES)-based plasma expander or PEG-albumin., Methods: Experiments were performed using the hamster skinfold window preparation. Human serum albumin that was surface decorated with PEG was compared with Voluven 6% (Fresenius Kabi, Austria; a starch solution that is of low molecular weight and has a low degree of substitution; HES). These plasma expanders were used for a 50% (blood volume) exchange transfusion to simulate preoperative hemodilution. Exchange transfusion was followed by a 60% (blood volume) hemorrhage to reproduce a severe surgical bleed over a 1 hour period. Observation of the animal was continued for another hour during the shock phase., Results: The PEG-albumin group exhibited significantly greater survival rate than did the HES group, in which none of the animals survived the hemorrhage phase of the experiment. Among the treatment groups there were no changes in mean arterial pressure and heart rate from baseline after hemodilution. Both groups experienced gradual increases in arterial oxygen tension and disturbance in acid-base balance, but this response was more pronounced in the HES group during the shock period. Mean arterial pressure remained elevated after the initial hemorrhage period in the PEG-albumin group but not in the HES group. Maintenance of a greater mean arterial pressure during the initial stages of hemorrhage is proposed to be in part due to the improved volume expansion with PEG-albumin, as indicated by the significant decrease in systemic hematocrit compared with the HES group. PEG-albumin treatment yielded higher functional capillary density during the initial stages of hemorrhage as compared with HES treatment., Conclusion: The ability of PEG-albumin to prolong maintenance of microvascular function better than HES is a finding that would be significant in a clinical setting involving preoperative blood management and extreme blood loss.

Published

2008

9. Extreme hemodilution with PEG-hemoglobin vs. PEG-albumin.

Author

Cabrales P, Tsai AG, Winslow RM, and Intaglietta M

Subjects

Animals, Blood Pressure physiology, Blood Substitutes analysis, Blood Substitutes chemistry, Cricetinae, Hemoglobins chemistry, Mesocricetus, Microcirculation cytology, Albumins analysis, Albumins chemistry, Hemodilution methods, Hemoglobins analysis, Microcirculation metabolism, Oxygen blood, Polyethylene Glycols chemistry

Abstract

Isovolemic hemodilution to 11% systemic hematocrit was performed in the hamster window chamber model using 6% dextran 70 kDa (Dx 70) and 5% human serum albumin (HSA). Systemic and microvascular effects of these solutions were compared with polyethylene glycol (PEG)-conjugated 5% albumin (MPA) and PEG-conjugated 4.2% Hb (MP4). These studies were performed for the purpose of comparing systemic and microvascular responses of PEG vs. non-PEG plasma expanders and similar oxygen-carrying vs. noncarrying blood replacement fluids. Mean arterial blood pressure was statistically significantly reduced for all groups compared with baseline (P < 0.05), HSA, MPA, and MP4 higher than Dx 70 (P < 0.05). MP4 and MPA had a significantly higher cardiac index than HSA and Dx 70, in addition to a positive base excess. Microvascular blood flow and capillary perfusion were significantly higher for the PEG compounds compared with HSA and Dx 70. Intravascular PO2 for MP4 and MPA was higher in arterioles (P < 0.05) compared with HSA and Dx 70, but there was no difference in either tissue or venular PO2 between groups. Total Hb in the MP4 group was 4.8 +/- 0.4 g/dl, whereas the remaining groups had a range of 3.6-3.8 g/dl. The hemodilution results showed that PEG compounds maintained microvascular conditions with lower concentrations than conventional plasma expanders. Furthermore, microvascular oxygen delivery and extraction in the window chamber tissue were significantly higher for the PEG compounds. MP4 was significantly higher than MPA (P < 0.05) and was not statistically different from baseline, an effect due to the additional oxygen release to the tissue by the Hb MP4.

Published

2005

10. Effects of extreme hemodilution with hemoglobin-based O2 carriers on microvascular pressure.

Author

Cabrales P, Tsai AG, Winslow RM, and Intaglietta M

Subjects

Animals, Arterioles physiology, Blood Pressure physiology, Capillaries physiology, Cricetinae, Mesocricetus, Microcirculation physiology, Vasoconstriction physiology, Venules physiology, Blood Pressure drug effects, Blood Substitutes pharmacology, Hemodilution, Hemoglobins pharmacology, Maleimides pharmacology, Polyethylene Glycols pharmacology, Skin blood supply

Abstract

A surface-modified polyethylene glycol-conjugated human hemoglobin (MP4) and alpha alpha-cross-linked human hemoglobin (alpha alpha Hb) were used to restore oxygen carrying capacity in conditions of extreme hemodilution (hematocrit 11%) in the hamster window model preparation. Changes in microvascular function were analyzed in terms of effects on capillary pressure and functional capillary density (FCD). MP4, at 1.0 +/- 0.2 g/dl blood concentration, significantly lowered mean arterial pressure (MAP) below baseline (99.6 +/- 7.6 mmHg) to 82.4 +/- 6.9 mmHg (P < 0.05) and decreased of FCD to 70 +/- 9%. alpha alpha Hb caused a greater recovery in MAP to 94.4 +/- 6.2 mmHg and lowered FCD to 62 +/- 8%. However, differences between alpha alpha Hb and MP4 in FCD were not statistically significant. Capillary pressures were in the ranges of 17-21 mmHg for MP4 and 15-19 mmHg for alpha alpha Hb, with both significantly lower than baseline (P < 0.05). Pressure in 80-microm-diameter arterioles was significantly increased with alpha alpha Hb relative to MP4 (P < 0.05). These results were compared with previous findings on the relation between capillary pressure and FCD; they supported the concept of a relationship between FCD and capillary pressure. Measurement of changes in arteriolar diameter, microvascular blood flow, and FCD show that there was no statistical difference between using alpha alpha Hb and MP4 in extreme hemodilution. Microvascular resistance in arterioles with a diameter range of 70-80 microm showed an increase relative to control with alpha alpha Hb, whereas MP4 caused a decrease.

Published

2005

11. Oxygen transport by low and normal oxygen affinity hemoglobin vesicles in extreme hemodilution.

Author

Cabrales P, Sakai H, Tsai AG, Takeoka S, Tsuchida E, and Intaglietta M

Subjects

Albumins, Animals, Arterioles, Blood Viscosity, Capillaries, Carbon Dioxide blood, Cricetinae, Exchange Transfusion, Whole Blood, Hematocrit, Male, Mesocricetus, Osmotic Pressure, Oxygen blood, Phospholipids blood, Phospholipids pharmacokinetics, Plasma Substitutes pharmacology, Venules, Blood Substitutes metabolism, Hemodilution, Hemoglobins metabolism, Oxygen pharmacokinetics

Abstract

The oxygen transport capacity of phospholipid vesicles encapsulating purified Hb (HbV) produced with a Po(2) at which Hb is 50% saturated (P 50 ) of 8 (HbV(8)) and 29 mmHg (HbV(29)) was investigated in the hamster chamber window model by using microvascular measurements to determine oxygen delivery during extreme hemodilution. Two isovolemic hemodilution steps were performed with 5% recombinant albumin (rHSA) until Hct was 35% of baseline. Isovolemic exchange was continued using HbV suspended in rHSA solution to a total [Hb] of 5.7 g/dl in blood. P(50) was modified by coencapsulating pyridoxal 5'-phosphate. Final Hct was 11% for the HbV groups, with a plasma [Hb] of 2.1 +/- 0.1 g/dl after exchange with HbV(8) or HbV(29). A reference group was hemodiluted to Hct 11% with only rHSA. All groups showed stable blood pressure and heart rate. Arterial oxygen tensions were significantly higher than baseline for the HbV groups and the rHSA group and significantly lower for the HbV groups compared with the rHSA group. Blood pressure was significantly higher for the HbV(8) group compared with the HbV(29) group. Arteriolar and venular blood flows were significantly higher than baseline for the HbV groups. Microvascular oxygen delivery and extraction were similar for the HbV groups but lower for the rHSA group (P < 0.05). Venular and tissue Po(2) were statistically higher for the HbV(8) vs. the HbV(29) and rHSA groups (P < 0.05). Improved tissue Po(2) is obtained when red blood cells deliver oxygen in combination with a high- rather than low-affinity oxygen carrier.

Published

2005

12. Elevated plasma viscosity in extreme hemodilution increases perivascular nitric oxide concentration and microvascular perfusion.

Author

Tsai AG, Acero C, Nance PR, Cabrales P, Frangos JA, Buerk DG, and Intaglietta M

Subjects

Animals, Arterioles physiology, Blood Pressure physiology, Blood Viscosity drug effects, Capillaries physiology, Cricetinae, Dextrans pharmacology, Mesocricetus, Nitric Oxide Synthase metabolism, Nitric Oxide Synthase Type III, Osmotic Pressure, Oxygen blood, Plasma Substitutes pharmacology, Stress, Mechanical, Venules physiology, Blood Viscosity physiology, Hemodilution, Nitric Oxide metabolism, Skin blood supply

Abstract

We tested the hypothesis that high-viscosity (HV) plasma in extreme hemodilution causes wall shear stress to be greater than low-viscosity (LV) plasma, leading to enhanced production of nitric oxide (NO). The perivascular concentration of NO was measured in arterioles and venules and the tissue of the hamster chamber window model, subjected to acute extreme hemodilution, with a hematocrit (Hct) of 11% using Dextran 500 (n = 6) or Dextran 70 (n = 5) with final plasma viscosities of 1.99 +/- 0.11 and 1.33 +/- 0.04 cp, respectively. HV plasma significantly increased the periarteriolar, perivenular, and tissue NO concentration by 2.0, 1.9, and 1.4 times the control (n = 7). The NO concentration with LV plasma was not statistically different from control. Arteriolar shear stress was significantly increased in HV plasma relative to LV plasma in arterioles but not in venules. Aortic endothelial NO synthase (eNOS) protein expression was increased with HV plasma but not with LV plasma. There was a weak correlation between perivascular NO concentration and the locally calculated shear stress induced by the procedures, when blood viscosity was corrected according to Hct values previously determined in studies of microvascular Hct distribution. The finding that the periarteriolar and venular NO concentration in HV plasma was the same although arteriolar shear stress was significantly greater than venular shear stress maybe be due to differences in vessel wall metabolism between arterioles and venules and the presence of NO transport through the blood stream in the microcirculation. Results support the concept that in extreme hemodilution HV plasma maintains functional capillary density through a NO-mediated vasodilatation.

Published

2005

13. Alginate plasma expander maintains perfusion and plasma viscosity during extreme hemodilution.

Author

Cabrales P, Tsai AG, and Intaglietta M

Subjects

Animals, Arterioles drug effects, Blood Pressure drug effects, Cricetinae, Hematocrit, Mesocricetus, Oxygen blood, Partial Pressure, Venules drug effects, Alginates pharmacology, Blood Viscosity drug effects, Glucuronic Acid pharmacology, Hemodilution methods, Hexuronic Acids pharmacology, Plasma Substitutes pharmacology

Abstract

Extreme hemodilution was performed in the hamster chamber window model using 6% Dextran 70, lowering systemic hematocrit by 60%. Animals were subsequently divided into three groups and hemodiluted to a hematocrit of 11% using 6% Dextran 70, 6% Dextran 500, and a 4% Dextran 70 + 0.7% alginate solution (n = 6 each group). Final plasma viscosities were 1.4 +/- 0.2, 2.2 +/- 0.1, and 2.7 +/- 0.2 cp, respectively, (P < 0.05, high viscosity vs. low viscosity). Blood viscosities were 2.1 +/- 0.2, 2.9 +/- 0.4, and 3.9 +/- 0.3 cp, respectively. The lowest blood and plasma viscosity group had a significantly lower functional capillary density, 37 +/- 16%, whereas the two high-viscosity solutions were 71 +/- 15% and 76 +/- 12% (P < 0.05, high viscosity vs. low viscosity), respectively. Arteriolar and venular flow in the Dextran 500 and alginate groups was higher than baseline (i.e., normal nontreated animals), whereas the low-viscosity group showed a reduction in flow. These microvascular changes were paralleled by changes in base excess, which was negative for the Dextran 70 group and positive for the other groups. However, tissue Po(2) was uniformly low for all groups (average of 1.4 mmHg). Calculation of tissue oxygen consumption in the window chamber based on the microvascular data, flow, and intravascular Po(2) showed that only the alginate + Dextran 70 solution-exchanged animals returned to baseline oxygen consumption, whereas the other groups were lower than baseline (P < 0.05). These results show that hemodilution performed with high-viscosity plasma expanders yields systemic arterial pressures and functional capillary densities that are significantly higher (P < 0.05) than those obtained with 6% Dextran 70, a fluid whose viscosity is similar to that of plasma. A condition for obtaining these results is that the oncotic pressure of the plasma expander be titrated to near normal, so that autotransfusion of fluid from the tissue into the vascular compartment does not reduce the effects of increasing plasma viscosity and increased shear stress on the microvascular wall.

Published

2005

14. Microvascular PO2 during extreme hemodilution with hemoglobin site specifically PEGylated at Cys-93(beta) in hamster window chamber.

Author

Cabrales P, Kanika ND, Manjula BN, Tsai AG, Acharya SA, and Intaglietta M

Subjects

Animals, Blood Pressure drug effects, Blood Viscosity drug effects, Cricetinae, Cysteine metabolism, Heart Rate drug effects, Male, Mesocricetus, Microcirculation drug effects, Partial Pressure, Hemodilution, Hemoglobins pharmacology, Hypovolemia physiopathology, Oxygen blood, Polyethylene Glycols pharmacology

Abstract

The oxygen transport capacity of nonhypertensive polyethylene glycol (PEG)-conjugated hemoglobin solutions were investigated in the hamster chamber window model. Microvascular measurements were made to determine oxygen delivery in conditions of extreme hemodilution [hematocrit (Hct) 11%]. Two isovolemic hemodilution steps were performed with a 6% Dextran 70 (70-kDa molecular mass) plasma expander until Hct was 35% of control. Isovolemic blood volume exchange was continued using two surface-modified PEGylated hemoglobins (P5K2, P(50) = 8.6, and P10K2, P(50) = 8.3; P(50) is the hemoglobin Po(2) corresponding to its 50% oxygen saturation) until Hct was 11%. P5K2 and P10K2 are PEG-conjugated hemoglobins that maintain most of the hemoglobin allosteric properties and have a cooperativity index of n = 2.2. The effects of these molecular solutions were compared with those obtained in a previous study using MP4, a PEG-modified hemoglobin whose P(50) was 5.4 and cooperativity was 1.2 (Tsai et al., Am J Physiol Heart Circ Physiol 285: H1411-H1419, 2003). Tissue oxygen levels were higher after P5K2 (7.0 +/- 2.5 mmHg) and P10K2 (6.3 +/- 2.3 mmHg) versus MP4 (1.7 +/- 0.5 mmHg) or the nonoxygen carrier Dextran 70 (1.3 +/- 1.2 mmHg). Microvascular oxygen delivery was higher after P5K2 and P10K2 (2.22 and 2.34 ml O(2)/dl blood) compared with MP4 (1.41 ml O(2)/dl blood) or Dextran 70 (0.90 ml O(2)/dl blood); however, all these values were lower than control (7.42 ml O(2)/dl blood). The total hemoglobin in blood was similar in all cases; therefore, the improvement in tissue Po(2) and oxygen delivery appears to be due to the increased cooperativity of the new molecules.

Published

2004

15. Oxygen delivery and consumption in the microcirculation after extreme hemodilution with perfluorocarbons.

Author

Cabrales P, Tsai AG, Frangos JA, Briceño JC, and Intaglietta M

Subjects

Animals, Biological Availability, Blood Flow Velocity, Capillaries anatomy & histology, Cardiac Output, Cricetinae, Erythrocytes physiology, Gases blood, Hemodynamics, Hydroxyethyl Starch Derivatives pharmacology, Mesocricetus, Microcirculation, Oxygen metabolism, Plasma Substitutes pharmacology, Fluorocarbons pharmacology, Hemodilution methods, Oxygen blood, Oxygen Consumption

Abstract

The oxygen transport capacity of fluorocarbons was investigated in the hamster chamber window model microcirculation to determine the rate at which oxygen is delivered to the tissue in conditions of extreme hemodilution [hematocrit (Hct) 11%]. Hydroxyethlyl starch (HES 200; 200 kDa molecular mass) was used as a plasma expander for two isovolemic hemodilutions performed with 10% HES 200 until a Hct of 65%. A third step reduced the Hct to 75% of baseline and was performed with either HES 200 or a 60% perfluorocarbon (PFC) emulsion. Comparisons of HES 200-only-hemodiluted animals versus 4.2 g/kg PFC emulsion-hemodiluted animals were made at 21% and 100% normobaric oxygen ventilation. It was found that systemic and microvascular oxygen delivery was 25% and 400% higher in the PFC animals compared with HES 200 animals, respectively, showing that PFCs deliver oxygen to the tissue when combined with hyperoxic ventilation in the present experiments, with no evidence of vasoconstriction or impaired microvascular function. Oxygen ventilation (100%) led to a positive base excess for the PFC group (5.5 +/- 2.5 mmol/l) versus a negative balance (-0.8 +/- 1.4 mmol/l) for the HES 200 group, suggesting that microvascular findings corresponded to systemic events.

Published

2004

16. Microvascular pressure and functional capillary density in extreme hemodilution with low- and high-viscosity dextran and a low-viscosity Hb-based O2 carrier.

Author

Cabrales P, Tsai AG, and Intaglietta M

Subjects

Animals, Carrier Proteins metabolism, Cattle blood, Cricetinae, Dextrans chemistry, Exchange Transfusion, Whole Blood, Hemodynamics, Hemoglobins metabolism, Mesocricetus, Plasma Substitutes chemistry, Viscosity, Blood Pressure, Blood Viscosity, Capillaries anatomy & histology, Capillaries physiology, Dextrans pharmacology, Hemodilution, Oxygen metabolism, Plasma Substitutes pharmacology

Abstract

Blood losses are usually corrected initially by the restitution of volume with plasma expanders and subsequently by the restoration of oxygen-carrying capacity using either a blood transfusion or possibly, in the near future, oxygen-carrying plasma expanders. The present study was carried out to test the hypothesis that high-plasma viscosity hemodilution maintains perfused functional capillary density (FCD) by preserving capillary pressure. Microvascular pressure responses to extreme hemodilution with low- (LV) and high-viscosity (HV) plasma expanders and an exchange transfusion with a polymerized bovine cell-free Hb (PBH) solution were analyzed in the awake hamster window chamber model (n = 26). Systemic hematocrit was reduced from 50% to 11%. PBH produced a greater mean arterial blood pressure than the nonoxygen carriers. FCD was higher after a HV plasma expander (70 +/- 15%) vs. PBH (47 +/- 12%). Microvascular pressure spanning the capillary network was higher after a HV plasma expander (16-19 mmHg) compared with PBH (12-16 mmHg) and a LV plasma expander (11-14 mmHg) but lower than control (22-26 mmHg). FCD was found to be directly proportional to capillary pressure. The use of a HV plasma expander in extreme hemodilution maintained the number of perfused capillaries and tissue perfusion by comparison with a LV plasma expander due to increased mean arterial blood pressure and capillary pressure. The use of PBH increased mean arterial pressure but reduced capillary pressure due to vasoconstriction and did not maintain FCD.

Published

2004

17. Radial displacement of red blood cells during hemodilution and the effect on arteriolar oxygen profile.

Author

Briceño JC, Cabrales P, Tsai AG, and Intaglietta M

Subjects

Animals, Arterioles physiology, Blood Flow Velocity physiology, Cricetinae, Diffusion, Hematocrit, Male, Mesocricetus, Stress, Mechanical, Erythrocytes physiology, Hemodilution, Oxygen blood

Abstract

In this study, we assessed the magnitude of the erratic deviations in the radial position of red blood cells (RBCs) in the laminar flow regime of arterioles in a hamster window preparation and the intraluminal Po(2) profile to determine whether this variability affects the intraluminal distribution of oxygen in conditions of normal hematocrit and hemodilution. A gated image intensifier was used to visualize fluorescently labeled RBCs in tracer quantities and obtain multiple measurements of RBC radial and longitudinal positions at time intervals on the order of 5 ms within single arterioles (diameter range 40-95 microm). RBCs in the velocity range of 0.3-14 mm/s exhibit a mean coefficient of variation of velocity of 16.9 +/- 10.5% and a SD of the radial position of 1.98 +/- 0.98 microm. Both quantities were inversely related to hematocrit, and the former was significantly lowered by hemodilution. Our experimental results presented very similar values and shape compared with the intraluminal oxygen profile derived theoretically for normal hematocrit, suggesting that shear-augmented diffusion due to the measured radial displacement of RBCs did not significantly affect oxygen diffusion from blood into the arteriolar vessel wall. Po(2) profiles in the arterioles assumed an increasingly parabolic configuration with increasing levels of hemodilution.

Published

2004

18. Nitric oxide synthase inhibition attenuates cardiac response to hemodilution with viscogenic plasma expander.

Author

Chatpun, Surapong and Cabrales, Pedro

Subjects

Blood viscosity, Endothelial nitric oxide synthase, Hemodilution, Nitric oxide, Ventricular function

Abstract

Background and objectivesIncreased vascular wall shear stress by elevated plasma viscosity significantly enhances the endothelial nitric oxide synthase (eNOS) activity during an acute isovolemic hemodilution. Also the modulation of plasma viscosity has effects on the cardiac function that were revealed if a left ventricular (LV) pressure-volume (PV) measurement was used. The aim of this study was to assess cardiac function responses to nitric oxide synthase (NOS) inhibitors with the presence of an elevated plasma viscosity but a low hematocrit level. Furthermore, systemic parameters were monitored in a murine model.Materials and methodsAs test group five anesthetized hamsters were administered with N(G)-nitro-L-arginine methyl ester (L-NAME), NOS inhibitor, whereas five other hamsters were used as control group without L-NAME infusion. The dosage of L-NAME was 10 mg/kg. An isovolemic hemodilution was performed by 40% of estimated blood volume with 6% w/v dextran 2000 kDa, high viscosity plasma expanders (PEs) with viscosity 6.34 cP. LV function was measured and assessed using a 1.4 Fr PV conductance catheter.ResultsThe study results demonstrated that NOS inhibition prevented the normal cardiac adaptive response after hemodilution. The endsystolic pressure increased 14% after L-NAME infusion and maintained higher than at the baseline after hemodilution, whereas it gradually decreased in the animals without L-NAME infusion. The admission of L-NAME significantly decreased the maximum rate of ventricular pressure rise (+dP/dtmax), stroke volume and cardiac output after hemodilution if compared to the control group (p

Published

2014

19. Effects of plasma viscosity modulation on cardiac function during moderate hemodilution

Author

Chatpun Surapong and Cabrales Pedro

Subjects

Cardiac function, hemodilution, plasma expander, plasma viscosity, Diseases of the blood and blood-forming organs, RC633-647.5

Abstract

Background : Previous studies have found that increasing plasma viscosity as whole blood viscosity decrease has beneficial effects in microvascular hemodynamics. As the heart couples with systemic vascular network, changes in plasma and blood viscosity during hemodilution determine vascular pressure drop and flow rate, which influence cardiac function. This study aimed to investigate how changes in plasma viscosity affect on cardiac function during acute isovolemic hemodilution. Materials and Methods: Plasma viscosity was modulated by hemodilution of 40% of blood volume with three different plasma expanders (PEs). Dextran 2000 kDa (Dx2M, 6.3 cP) and dextran 70 kDa (Dx70, 3.0 cP) were used as high and moderate viscogenic PEs, respectively. Polyethylene glycol conjugated with human serum albumin (PEG-HSA, 2.2 cP) was used as low viscogenic PE. The cardiac function was assessed using a miniaturized pressure-volume conductance catheter. Results: After hemodilution, pressure dropped to 84%, 79%, and 78% of baseline for Dx2M, Dx70 and PEG-HSA, respectively. Cardiac output markedly increased for Dx2M and PEG-HSA. Dx2M significantly produced higher stroke work relative to baseline and compared to Dx70. Conclusion: Acute hemodilution with PEG-HSA without increasing plasma viscosity provided beneficial effects on cardiac function compared to Dx70, and similar to those measured with Dx2M. Potentially negative effects of increasing peripheral vascular resistance due to the increase in plasma viscosity were prevented.

Published

2010

20. Hemorheological implications of perfluorocarbon based oxygen carrier interaction with colloid plasma expanders and blood.

Author

Vásquez, Diana M., Ortiz, Daniel, Alvarez, Oscar A., Briceño, Juan C., and Cabrales, Pedro

Subjects

PERFLUOROCARBONS, OXYGEN carriers, COLLOIDS, EMULSIONS, BLOOD testing, ELECTROSTATIC analyzers, ELECTROLYTES

Abstract

Perfluorocarbon (PFC) emulsions used as artificial oxygen carriers lack colloid osmotic pressure (COP) and must be administered with colloid-based plasma expanders (PEs). Although PFC emulsions have been widely studied, there is limited information about PFC emulsion interaction with PEs and blood. Their interaction forms aggregates due to electrostatic and rheological phenomena, and change blood rheology and blood flow. This study analyzes the effects of the interaction between PFC emulsions with blood in the presence of clinically-used PEs. The rheological behavior of the mixtures was analyzed in vitro in parallel with in vivo analysis of blood flow in the microcirculation using intravital microscopy, when PEs were administered in a clinically relevant scenario. The interaction between the PFC emulsion and PE with blood produced PFC droplets and red blood cell (RBCs) aggregation and increased blood viscosity in a shear dependent fashion. The PFC droplets formed aggregates when mixed with PEs containing electrolytes, and the aggregation increased with the electrolyte concentration. Mixtures of PFC with PEs that produced PFC aggregates also induced RCBs aggregation when mixed with blood, increasing blood viscosity at low shear rates. The more viscous suspension at low shear rates produced a blunted blood flow velocity profile in vivo compared to nonaggregating mixtures of PFC and PEs. For the PEs evaluated, human serum albumin produced minimal to undetectable aggregation. PFC and PEs interaction with blood can affect sections of the microcirculation with low shear rates (e.g., arterioles, venules, and pulmonary circulation) when used in a clinical setting, because persistent aggregates could cause capillary occlusion, decreased perfusion, pulmonary emboli or focal ischemia. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:796-807, 2013 [ABSTRACT FROM AUTHOR]

Published

2013

21. Plasma expander and blood storage effects on capillary perfusion in transfusion after hemorrhage.

Author

Hightower, C. Makena, Salazar Vázquez, Beatriz Y., Cabrales, Pedro, Tsai, Amy G., Acharya, Seetharama A., and Intaglietta, Marcos

Subjects

BLOOD plasma, BLOOD collection, BLOOD banks, PERFUSION, BLOOD transfusion, HEMORRHAGE, BLOOD volume, HEMODILUTION

Abstract

BACKGROUND: Treating hemorrhage with blood transfusions in subjects previously hemodiluted with different colloidal plasma expanders, using fresh autologous blood or blood that has been stored for 2 weeks, allows identifying the interaction between type of plasma expander and differences in blood storage. STUDY DESIGN AND METHODS: Studies used the hamster window chamber model. Fresh autologous plasma, 130-kDa starch-based plasma expander (hydroxyethyl starch [HES]), or 4% polyethylene glycol-conjugated albumin (PEG-Alb) was used for 20% of blood volume (BV) hemodilution. Hemodilution was followed by a 55% by BV 40-minute hemorrhagic shock period, treated with transfusion of fresh or blood that was stored for 2 weeks. Outcome was evaluated 1 hour after blood transfusion in terms of microvascular and systemic variables. RESULTS: Results were principally dependent on the type of colloidal solution used during hemodilution, 4% PEG-Alb yielding the best microvascular recovery evaluated in terms of the functional capillary density. This result was consistent whether fresh blood or stored blood was used in treating the subsequent shock period. Fresh blood results were significantly better in systemic and microvascular terms relative to stored blood. HES and fresh plasma hemodilution yielded less favorable results, a difference that was enhanced when fresh versus stored blood was compared in their efficacy of correcting the subsequent hemorrhage. CONCLUSION: The type of plasma expander used for hemodilution influences the short-term outcome of subsequent volume resuscitation using blood transfusion, 4% PEG-Alb providing the most favorable outcome by comparison to HES or fresh plasma. [ABSTRACT FROM AUTHOR]

Published

2013

22. PEG-albumin supraplasma expansion is due to increased vessel wall shear stress induced by blood viscosity shear thinning.

Author

Sriram, Krishna, Tsai, Amy G., Cabrales, Pedro, Fantao Meng, Acharya, Seetharama A., Tartakovsky, Daniel M., and Intaglietta, Marcos

Abstract

We studied the extreme hemodilution to a hematocrit of 11% induced by three plasma expanders: polyethylene glycol (PEG)-conjugated albumin (PEG-Alb), 6% 70-kDa dextran, and 6% 500-kDa dextran. The experimental component of our study relied on microelectrodes and cardiac output to measure both the rheological properties of plasmaexpander blood mixtures and nitric oxide (NO) bioavailability in vessel walls. The modeling component consisted of an analysis of the distribution of wall shear stress (WSS) in the microvessels. Our experiments demonstrated that plasma expansion with PEG-Alb caused a state of supraperfusion with cardiac output 40% above baseline, significantly increased NO vessel wall bioavailability, and lowered peripheral vascular resistance. We attributed this behavior to the shear thinning nature of blood and PEG-Alb mixtures. To substantiate this hypothesis, we developed a mathematical model of non-Newtonian blood flow in a vessel. Our model used the Quemada rheological constitutive relationship to express blood viscosity in terms of both hematocrit and shear rate. The model revealed that the net effect of the hemodilution induced by relatively low-viscosity shear thinning PEG-Alb plasma expanders is to reduce overall blood viscosity and to increase the WSS, thus intensifying endothelial NO production. These changes act synergistically, significantly increasing cardiac output and perfusion due to lowered overall peripheral vascular resistance. [ABSTRACT FROM AUTHOR]

Published

2012

23. Reduction of Oxygen-Carrying Capacity Weakens the Effects of Increased Plasma Viscosity on Cardiac Performance in Anesthetized Hemodilution Model.

Author

Chatpun, Surapong and Cabrales, Pedro

Subjects

*OXYGEN carriers, *BLOOD plasma, *VISCOSITY, *CARDIAC output, *ANESTHESIA, *HEMODILUTION

Abstract

We investigated the effects of reduced oxygen-carrying capacity on cardiac function during acute hemodilution, while the plasma viscosity was increased in anesthetized animals. Two levels of oxygen-carrying capacity were created by 1-step and 2- step hemodilution in male golden Syrian hamsters. In the 1-step hemodilution (1-HD), 40% of the animals' blood volume (BV) was exchanged with 6% dextran 70 kDa (Dx70) or dextran 2000 kDa (Dx2M). In the 2-step hemodilution (2-HD), 25% of the animals' BV was exchanged with Dx70 followed by 40% BV exchanged with Dx70 or Dx2M after 30 minutes of first hemodilution. Oxygen delivery in the 2-HD group consequently decreased by 17% and 38% compared to that in the 1-HD group hemodiluted with Dx70 and Dx2M, respectively. End-systolic pressure and maximum rate of pressure change in the 2-HD group significantly lowered compared with that in the 1-HD group for both Dx70 and Dx2M. Cardiac output in the 2-HD group hemodiluted with Dx2M was significantly higher compared with that hemodiluted with Dx70. In conclusion, increasing plasma viscosity associated with lowering oxygen-carrying capacity should be considerably balanced to maintain the cardiac performance, especially in the state of anesthesia. [ABSTRACT FROM AUTHOR]

Published

2012

24. Nonlinear cardiovascular regulation consequent to changes in blood viscosity.

Author

Jung, F., Clevert, D., Vázquez, Beatriz Y. Salazar, Cabrales, Pedro, Tsai, Amy G., and Intaglietta, Marcos

Subjects

BLOOD viscosity, CARDIOVASCULAR diseases, HEMATOCRIT, NITRIC oxide, MICROCIRCULATION

Abstract

Increasing blood and plasma viscosity is generally associated with pathological conditions, and increased cardiovascular risk, a perception based in part on studies where blood viscosity is increased to extreme values attained by hemoconcentration. Present studies, supported by epidemiological studies in humans, show that moderate increases in Hct improve cardiovascular function and vice versa. This result is due to the nonlinear regulation of peripheral vascular resistance arising from the increased production of nitric oxide following the increase of shear stress on the vascular wall due to increasing blood viscosity. Similar effects are found in when plasma viscosity is increased in the extremely hemodiluted circulation. In both cases there is an effect at the arteriolar/capillary level, leading to a condition of improved microvascular function and supra perfusion that facilitates clearance of metabolic waste products, while maintaining oxygen delivery. Application of these findings to the design of viscogenic plasma expanders suggests a new approach for the treatment of hemorrhage that in part replaces the use of blood transfusions, making it feasible to lower the transfusion trigger to levels below than normally considered safe. [ABSTRACT FROM AUTHOR]

Published

2011

25. Synthesis and biophysical properties of polymerized human serum albumin.

Author

Elmer, Jacob, Cabrales, Pedro, Qi Wang, Ning Zhang, and Palmer, Andre F.

Subjects

ERYTHROCYTES, CELL aggregation, NEPHROTOXICOLOGY, EXTRAVASATION, ALBUMINS, GLUTARALDEHYDE, CROSSLINKING (Polymerization), DICHROISM

Abstract

The use of many plasma expanders (PEs) is often limited by undesirable side effects, such as red blood cell (RBC) aggregation (hydroxyethyl starch), nephrotoxicity (dextran), and extravasation (albumin). Despite its natural prevalence in the bloodstream, human serum albumin (HSA) can increase the risk of mortality when administered to patients with increased vascular permeability (i.e., patients suffering from burns, septic shock, and endothelial dysfunction). The harmful extravasation of HSA can be limited by polymerizing HSA to increase its molecular size. In this study, HSA was nonspecifically cross-linked with glutaraldehyde at different cross-link densities by varying the molar ratio of glutaraldehyde to HSA. The results of this study show that the weight-averaged molecular weight (MW), viscosity, and extent of RBC aggregation of polymerized HSA increases with increasing cross-link density, whereas the colloid osmotic pressure (COP) decreases with increasing cross-link density. Interestingly, circular dichroism measurements indicate that the secondary structure of HSA is unaffected by polymerization. Altogether, these results show that glutaraldehyde can effectively cross-link HSA to produce high MW polymers, yielding a novel series of potential PEs that exhibit low COP and high viscosity. © 2011 American Institute of Chemical Engineers Biotechnol. Prog., 2011 [ABSTRACT FROM AUTHOR]

Published

2011

26. Effects of plasma viscosity modulation on cardiac function during moderate hemodilution.

Author

Surapong Chatpun and Cabrales, Pedro

Subjects

*HEART, *HEMODILUTION, *BLOOD viscosity, *MICROCIRCULATION disorders, *HEMODYNAMICS, *SERUM albumin

Abstract

Background: Previous studies have found that increasing plasma viscosity as whole blood viscosity decrease has beneficial effects in microvascular hemodynamics. As the heart couples with systemic vascular network, changes in plasma and blood viscosity during hemodilution determine vascular pressure drop and flow rate, which influence cardiac function. This study aimed to investigate how changes in plasma viscosity affect on cardiac function during acute isovolemic hemodilution. Materials and Methods: Plasma viscosity was modulated by hemodilution of 40% of blood volume with three different plasma expanders (PEs). Dextran 2000 kDa (Dx2M, 6.3 cP) and dextran 70 kDa (Dx70, 3.0 cP) were used as high and moderate viscogenic PEs, respectively. Polyethylene glycol conjugated with human serum albumin (PEG-HSA, 2.2 cP) was used as low viscogenic PE. The cardiac function was assessed using a miniaturized pressure-volume conductance catheter. Results: After hemodilution, pressure dropped to 84%, 79%, and 78% of baseline for Dx2M, Dx70 and PEG-HSA, respectively. Cardiac output markedly increased for Dx2M and PEG-HSA. Dx2M significantly produced higher stroke work relative to baseline and compared to Dx70. Conclusion: Acute hemodilution with PEG-HSA without increasing plasma viscosity provided beneficial effects on cardiac function compared to Dx70, and similar to those measured with Dx2M. Potentially negative effects of increasing peripheral vascular resistance due to the increase in plasma viscosity were prevented. [ABSTRACT FROM AUTHOR]

Published

2010

27. Tissue oxygenation after exchange transfusion with ultrahigh-molecular-weight tense- and relaxed-state polymerized bovine hemoglobins.

Author

Cabrales, Pedro, Yipin Zhou, Harris, David R., and Palmer, Andre F.

Subjects

*ANEMIA treatment, *HEMODILUTION, *HYPERBARIC oxygenation, *TREATMENT of cattle diseases, *HEMOGLOBINS, *HEMODYNAMICS, *VASOCONSTRICTION, *PHYSIOLOGY

Abstract

Hemoglobin (Hb)-based O2 carriers (HBOCs) constitute a class of therapeutic agents designed to correct the O2 deficit under conditions of anemia and traumatic blood loss. The O2 transport capacity of ultrahigh-molecular-weight bovine Hb polymers (PolybHb), polymerized in the tense (T) state and relaxed (R) state, were investigated in the hamster chamber window model using microvascular measurements to determine O2 delivery during extreme anemia. The anemic state was induced by hemodilution with a plasma expander (70-Wa dextran). After an initial moderate hemodilution to 18% hematocrit, animals were randomly assigned to exchange transfusion groups based on the type of PolybHb solution used (namely, T-state PolybHb and R-state PolybHb groups). Measurements of systemic parameters, microvascular hemodynamics, capillary perfusion, and intravascular and tissue 02 levels were performed at 11% hematocrit. Both PolybHbs were infused at 10 g/dl, and their viscosities were higher than nondiluted blood. Restitution of the O2 carrying capacity with T-state PolybHb exhibited lower arterial pressure and higher functional capillary density compared with R- state PolybHb. Central arterial O2 tensions increased significantly for R-state PolybHb compared with T-state PolybHb; conversely, microvascular O2 tensions were higher for T-state PolybHb compared with R-state PolybHb. The increased tissue PO2 attained with T-state PolybHb results from the larger amount of O2 released from the PolybHb and maintenance of macrovascular and microvascular hemodynamics compared with R-state PolybHb. These results suggest that the extreme high O2 affinity of R-state PolybHb prevented O2 bound to PolybHb from been used by the tissues. The results presented here show that T-state PolybHb, a high-viscosity O2 carrier, is a quintessential example of an appropriately engineered O2 carrying solution, which preserves vascular mechanical stimuli (shear stress) lost during anemic conditions and reinstates oxygenation, without the hypertensive or vasoconstriction responses observed in previous generations of HBOCs. [ABSTRACT FROM AUTHOR]

Published

2010

28. Isovolemic exchange transfusion with increasing concentrations of low oxygen affinity hemoglobin solution limits oxygen delivery due to vasoconstriction.

Author

Cabrales, Pedro, Tsai, Amy G., and Intaglietta, Marcos

Subjects

*VASOCONSTRICTION, *HEMOGLOBIN polymorphisms, *HEMOGLOBINS, *ANEMIA, *HEMODILUTION, *BOVINE leukosis

Abstract

Cabrales P, Tsai AG, Intaglietta M. Isovolemic exchange transfusion with increasing concentrations of low oxygen affinity hemoglobin solution limits oxygen delivery due to vasoconstriction. Am J Physiol Heart Circ Physiol 295: H221 2-H22 18, 2008. First published October 3, 2008; doi: 10.1152/ajpheart.00751.2008.-02-carrying fluids based on hemoglobin (Hb) are in various stages of clinical trials to determine their suitability as O[sub2]-carrying plasma expanders. Polymerized Hb solutions are characterized by their vasoactivity, low O[sub2] affinity, oncotic effect, prolonged shelf life, and stability. Physiological responses to facilitated O[sub2] transport after exchange transfusion with polymerized bovine Hb (PBH) were studied in the hamster window chamber model during acute moderate anemia to determine how PBH affects microvascular perfusion and tissue oxygenation. The anemic state [29% hematocrit (Hct)] was induced by hemodilution with a plasma expander (70 kDa dextran). After hemodilution, animals were randomly assigned to different exchange transfusion groups. Study groups were based on the concentration of PBH used, namely: PBH at 13 g Hb/dl [PBHI3], PBH diluted to 8 (PBH8) or 4 (PBH4) g Hb/dl in albumin solution at matching colloidal osmotic pressure (COP), and no PBH (only albumin solution) at matching COP (PBHO). Measurement of systemic parameters, microvascular hemodynamics, capillary perfusion, and intravascular and tissue O[sub2] levels was performed at 18% Hct. Restitution of O[sub2]-carrying capacity with PBHI3 increased arterial pressure and triggered vasoconstriction, low perfusion, and high peripheral resistance. PBH4 and PBHO exhibited lower arterial pressures compared with PBH13. Exchange transfused animals with PBH8 and PBH4 better maintained perfusion and functional capillary density than PBHI3. Blood gas parameters and acid-base balance were recovered proportional to microvascular perfusion. Arterial O[sub2] tensions were improved with PBH4 and PBH8 by preventing O[sub2] precapillary release and increasing O[sub2] reserve. Further studies to establish PBH optimal dosage, efficacy, safety, and its effect on outcome are indicated before Hb-based O[sub2]-carrying blood substitutes are implemented in routine practice. [ABSTRACT FROM AUTHOR]

Published

2008

29. Increased plasma viscosity prolongs microhemodynamic conditions during small volume resuscitation from hemorrhagic shock

Author

Cabrales, Pedro, Tsai, Amy G., and Intaglietta, Marcos

Subjects

*HEMORRHAGIC shock, *ARTERIAL injuries, *HEMORRHAGE, *BLOOD circulation

Abstract

Summary: Systemic and microvascular hemodynamic responses to hemorrhagic shock resuscitation with hypertonic saline (HTS, 7.5% NaCl) followed with a small volume of plasma expander were studied in the hamster window chamber model to determine the role of plasma expander viscosity in the acute resuscitation outcome. Moderate hemorrhagic shock was induced by arterial controlled bleeding of 50% of blood volume (BV) and the hypovolemic state was maintained for 1h. Volume restitution was performed by infusion of HTS, 3.5% of BV followed by 10% of BV plasma expanders. Resuscitation was followed for 90min. The experimental groups were named based on the plasma expanders infused after the HTS, namely: [Hextend], Hextend® (6% Hetastarch 670kDa in lactated electrolyte solution, 4 cp), [Hextend+V], Hextend® with viscosity enhanced by the addition of 0.4% alginate, 8 cp, and [NVR] no volume resuscitation as control group. Measurement of systemic parameters, microvascular hemodynamics and capillary perfusion were performed during hemorrhage, shock and resuscitation. Restitution with Hextend yielded the higher mean arterial pressure (MAP), followed by Hextend+V and NVR. Increasing plasma viscosity did not increase peripheral vascular resistance. Functional capillary density (FCD) was higher for Hextend+V than Hextend and NVR. The level of restoration of acid–base balance correlated with microvascular perfusion and was significantly improved with Hextend+V when compared to Hextend and NVR. These results suggest the importance of restoration of blood rheological properties through enhancing plasma viscosity, influencing the re-establishment of microvascular perfusion during small volume resuscitation from hemorrhagic shock. [Copyright &y& Elsevier]

Published

2008

30. Modulation of Perfusion and Oxygenation by Red Blood Cell Oxygen Affinity during Acute Anemia.

Author

Cabrales, Pedro, Tsai, Amy G., and Intaglietta, Marcos

Published

2008

31. Resuscitation from hemorrhagic shock: recovery of oxygen carrying capacity or perfusion? Efficacy of new plasma expanders.

Author

TSAI, AMY G., CABRALES, PEDRO, ACHARYA, SEETHARAMA A., and INTAGLIETTA, MARCOS

Subjects

*HEMORRHAGIC shock, *PLASMA exchange (Therapeutics), *OXYGEN carriers, *PERFUSION, *POLYETHYLENE glycol, *BLOOD transfusion

Abstract

Potential shortages and perceived issues with the biosafety of blood have strengthened interest in the search for alternatives to blood. Currently available plasma expanders are effective in recovering pressure by volume expansion but are not safely deployed beyond the transfusion trigger. Conventional reasoning indicates that this limitation relates to oxygen carrying capacity reaching the threshold where it no longer can satisfy the metabolic demand of the organism; however, recent findings show that this limitation is also determined by other physical factors such as their viscosity and colloidal osmotic pressure. These fluid transport properties have a strong influence on the maintenance of microvascular perfusion and function in conditions of extreme hemodilution that obtain when resuscitation is continued beyond the transfusion trigger with plasma expanders. This realization leads to the possibility of developing new plasma expanders whose physical properties enhance microvascular function compensating for the decreased intrinsic oxygen carrying capacity in extreme hemodilution via enhanced microvascular perfusion. This review presents experimental, systemic and microvascular findings obtained using polyethylene glycol conjugated albumin solutions in extreme hemodilution and shock resuscitation in the hamster window chamber model, concluding that plasma expanders of this type can be effectively used beyond the transfusion trigger. [ABSTRACT FROM AUTHOR]

Published

2007

32. Transfusion restores blood viscosity and reinstates microvascular conditions from hemorrhagic shock independent of oxygen carrying capacity

Author

Cabrales, Pedro, Intaglietta, Marcos, and Tsai, Amy G.

Subjects

*BLOOD transfusion, *BLOOD viscosity, *MICROCIRCULATION disorders, *HEMORRHAGIC shock, *THERAPEUTICS, *HEMORRHAGIC shock treatment, *ANIMALS, *BLOOD flow measurement, *BLOOD volume, *RED blood cell transfusion, *HAMSTERS, *HEMATOCRIT, *HEMODYNAMICS, *MICROCIRCULATION, *OXYGEN, *RESEARCH funding, *RESUSCITATION

Abstract

Summary: Systemic and microvascular hemodynamic responses to transfusion of oxygen using functional and non-functional packed fresh red blood cells (RBCs) from hemorrhagic shock were studied in the hamster window chamber model to determine the significance of RBCs on rheological and oxygen transport properties. Moderate hemorrhagic shock was induced by arterial controlled bleeding of 50% of the blood volume, and a hypovolemic state was maintained for 1h. Volume restitution was performed by infusion of the equivalent of 2.5units of packed cells, and the animals were followed for 90min. Resuscitation study groups were non-oxygen functional fresh RBCs where the hemoglobin (Hb) was converted to methemoglobin (MetHb) [MetRBC], fully oxygen functional fresh RBCs [OxyRBC] and 10% hydroxyethyl starch [HES] as a volume control solution. Measurement of systemic variables, microvascular hemodynamics and capillary perfusion were performed during the hemorrhage, hypovolemic shock and resuscitation. Final blood viscosities after the entire protocol were 3.8cP for transfusion of RBCs and 2.9cP for resuscitation with HES (baseline: 4.2cP). Volume restitution with RBCs with or without oxygen carrying capacity recovered higher mean arterial pressure (MAP) than HES. Functional capillary density (FCD) was substantially higher for transfusion versus HES, and the presence of MetHb in the fresh RBC did not change FCD or microvascular hemodynamics. Oxygen delivery and extraction were significantly lower for resuscitation with HES and MetRBC compared to OxyRBC. Incomplete re-establishment of perfusion after resuscitation with HES could also be a consequence of the inappropriate restoration of blood rheological properties which unbalance compensatory mechanisms, and appear to be independent of the reduction in oxygen carrying capacity. [Copyright &y& Elsevier]

Published

2007

33. Effects of erythrocyte flexibility on microvascular perfusion and oxygenation during acute anemia.

Author

Cabrales, Pedro

Subjects

*ERYTHROCYTES, *PERFUSION, *ANEMIA, *HEMATOCRIT, *HEMODILUTION

Abstract

Responses to exchange transfusion using red blood cells (RBCs) with normal and reduced flexibility were studied in the hamster window chamber model during acute moderate isovolemic hemodilution to determine the role of RBC membrane stiffness in microvascular perfusion and tissue oxygenation. Erythrocyte stiffness was increased by 30-mm incubation in 0.02% glutaraldehyde solution, and unreacted glutaraldehyde was completely removed. Filtration pressure through 5-µm pore size filters was used to quantify stiffness of the RBCs. Anemic conditions were induced by two isovolemic hemodilution steps using 6% 70-kDa dextran to a hematocrit (Hct) of 18% (moderate hemodilution). The protocol continued with an exchange transfusion to reduce native RBCs to 75% of baseline (11% Hct) with either fresh RBCs (RBC group) or reduced-flexibility RBCs (GRBC group) suspended in 5% albumin at 18% Hct; a plasma expander (6% 70-kDa dextran; Dex70 group) was used as control. Systemic parameters, microvascular perfusion, capillary perfusion [functional capillary density (FCD)], and oxygen levels across the microvascular network were measured by noninvasive methods. RBC deformability for GRBCs was significantly decreased compared with RBCs and moderate hemodilution conditions. The GRBC group had a greater mean arterial blood pressure (MAP) than the RBC and Dex70 groups. FCD was substantially higher for RBC (0.81 ± 0.07 of baseline) vs. GRBC (0.32 ± 0.10 of baseline) and Dex70 (0.38 ± 0.10 of baseline) groups. Microvascular tissue Po2 was significantly lower for Dex70 and GRBC vs. RBC groups and the moderate hemodilution condition. Results were attributed to decreased oxygen uploading in the lungs and obstruction of tissue capillaries by rigidified RBCs, indicating that the effects impairing RBC flexibility are magnified at the microvascular level, where perfusion and oxygenation may define transfusion outcome. [ABSTRACT FROM AUTHOR]

Published

2007

34. Blood viscosity maintains microvascular conditions during normovolemic anemia independent of blood oxygen-carrying capacity.

Author

Cabrales, Pedro, Martini, Judith, Intaglietta, Marcos, and Tsai, Amy G.

Subjects

*ERYTHROCYTES, *BLOOD transfusion, *METHEMOGLOBINEMIA, *HEMODILUTION, *BLOOD viscosity, *MICROCIRCULATION, *METHYLENE blue

Abstract

Responses to exchange transfusion with red blood cells (RBCs) containing methemoglobin (MetRBC) were studied in an acute isovolemic hemodiluted hamster window chamber model to determine whether oxygen content participates in the regulation of systemic and micro-vascular conditions during extreme hemodilution. Two isovolemic hemodilution steps were performed with 6% dextran 70 kDa (Dex70) until systemic hematocrit (Hct) was reduced to 18% (Level 2). A third-step hemodilution reduced the functional Hct to 75% of baseline by using either a plasma expander (Dex70) or blood adjusted to 18% Hct with all MetRBCs. In vivo functional capillary density (FCD), microvascular perfusion, and oxygen distribution in microvascular networks were measured by noninvasive methods. Methylene blue was administered intravenously to reduce methemoglobin (rRBC), which increased oxygen content with no change in Hct or viscosity from MetRBC. Final blood viscosities after the entire protocol were 2.1 cP for Dex70 and 2.8 cP for MetRBC (baseline, 4.2 cP). MetRBC had a greater mean arterial pressure (MAP) than did Dex70. FCD was substantially higher for MetRBC [82 (SD 6) of baseline] versus Dex70 [38 (SD 10) of baseline], and reduction of methemoglobin to oxyhemoglobin did not change FCD [84% (SD 5) of baseline]. Po2 levels measured with palladium-meso-tetra(4-carboxyphenyl)porphyfin phosphorescence were significantly changed for Dex70 and MetRBC compared with Level 2 (Hct 18%). Reduction of methemoglobin to oxyhemoglobin partially restored Po2 to Level 2. Wall shear rate and wall shear stress decreased in arterioles and venules for Dex70 and did not change for MetRBC or rRBC. Increased MAP and shear stress-mediated factors could be the possible mechanisms that improved perfusion flow and FCD after exchange for MetRBC. Thus the fall in systemic and microvascular conditions during extreme hemodilution with low-viscosity plasma expanders seems to be, in part, from the decrease in blood viscosity independent of the reduction in oxygen content. [ABSTRACT FROM AUTHOR]

Published

2006

35. Oxygen release from arterioles with normal flow and no-flow conditions.

Author

Cabrales, Pedro, Tsai, Amy G., Johnson, Paul C., and Intaglietta, Marcos

Subjects

PHYSIOLOGICAL transport of oxygen, PHOSPHORESCENCE, HEMODILUTION, TREATMENT of blood circulation disorders, CARDIOVASCULAR diseases, TISSUES

Abstract

The rate of oxygen release from arterioles (∼55 μm diameter) was measured in the hamster window chamber model during flow and no-flow conditions. Flow was stopped by microvascular transcutaneous occlusion using a glass pipette held by a manipulator. The reduction of the intra-arteriolar oxygen tension (Po2) was measured by the phosphorescence quenching of preinfused Pd-porphyrin, 100 μm downstream from the occlusion. Oxygen release from arterioles was found to be 53% greater during flow than no-flow conditions (2.6 vs. 1.7 × 10-5 ml O2·cm-2·s-1 P < 0.05). Acute hemodilution with dextran 70 was used to reduce vessel oxygen content, significantly increase wall shear stress (14%, P < 0.05), reduce Hct to 28.4% (SD 1.0) [vs. 48.8% (SD 1.8) at baseline], lower oxygen supply by the arterioles (10%, P < 0.05), and increase oxygen release from the arterioles (39%, P < 0.05). Hemodilution also increased microcirculation oxygen extraction (33% greater than nonhemodilution, P < 0.05) and oxygen consumption by the vessel wall, as shown by an increase in vessel wall oxygen gradient [difference in Po2 between the blood and the tissue side of the arteriolar wall, nonhemodiluted 16.2 Torr (SD 1.0) vs. hemodiluted 18.3 Torr (SD 1.4), P < 0.05]. Oxygen released by the arterioles during flow vs. nonflow was increased significantly after hemodilution (3.6 vs. 1.8 × 10-5 ml O2·cm-2·s-1, P < 0.05). The oxygen cost induced by wall shear stress, suggested by our findings, may be > 15% of the total oxygen delivery to tissues by arterioles during flow in this preparation. [ABSTRACT FROM AUTHOR]

Published

2006

36. Effects of extreme hemodilution with hemoglobin-based O2 carriers on microvascular pressure.

Author

Cabrales, Pedro, Tsai, Amy G., Winslow, Robert M., and Intaglietta, Marcos

Subjects

*HEMODILUTION, *HEMOGLOBINS, *BLOOD proteins, *OXYGEN in the body, *BLOOD plasma, *PROTEINS, *BLOOD flow

Abstract

A surface-modified polyethylene glycol-conjugated human hemoglobin (MP4) and αα-cross-linked human hemoglobin (ααHb) were used to restore oxygen carrying capacity in conditions of extreme hemodilution (hematocrit 11%) in the hamster window model preparation. Changes in microvascular function were analyzed in terms of effects on capillary pressure and functional capillary density (FCD). MP4, at 1.0 ± 0.2 g/dl blood concentration, significantly lowered mean arterial pressure (MAP) below baseline (99.6 ± 7.6 mmHg) to 82.4 ± 6.9 mmHg (P <0.05) and decreased of FCD to 70 ± 9%. ααHb caused a greater recovery in MAP to 94.4 ± 6.2 mmHg and lowered FCD to 62 ± 8%. However, differences between ααHb and MP4 in FCD were not statistically significant. Capillary pressures were in the ranges of 17–21 mmHg for MP4 and 15–19 mmHg for ααHb, with both significantly lower than baseline (P < 0.05). Pressure in 80-μm- diameter arterioles was significantly increased with ααHb relative to MP4 (P < 0.05). These results were compared with previous findings on the relation between capillary pressure and FCD; they supported the concept of a relationship between FCD and capillary pressure. Measurement of changes in arteriolar diameter, microvascular blood flow, and FCD show that there was no statistical difference between using ααHb and MP4 in extreme hemodilution. Microvascular resistance in arterioles with a diameter range of 70–80 μm showed an increase relative to control with αα00Hb, whereas MP4 caused a decrease. [ABSTRACT FROM AUTHOR]

Published

2005

37. Microvascular Po2 during extreme hemodilution with hemoglobin site specifically PEGylated at Cys-93(β) in hamster window chamber.

Author

Cabrales, Pedro, Kanika, Nirmala Devi, Manjula, Belur N., Tsai, Amy G., Acharya, Seetharama A., and Intaglietta, Marcos

Subjects

*HEMODILUTION, *TREATMENT of blood circulation disorders, *HEMOGLOBINS, *POLYETHYLENE glycol, *OXYGEN, *TISSUES

Abstract

The oxygen transport capacity of nonhypertensive polyethylene glycol (PEG)conjugated hemoglobin solutions were investigated in the hamster chamber window model. Microvascular measurements were made to determine oxygen delivery in conditions of extreme hemodilution [hematocrit (Hct) 11%]. Two isovolemic hemodilution steps were performed with a 6% Dextran 70 (70-kDa molecular mass) plasma expander until Hct was 35% of control. Isovolemic blood volume exchange was continued using two surface-modified PEGylated hemoglobins (P5K2, P50 = 8.6, and P10K2, P50 = 8.3; P50 is the hemoglobin PO2 corresponding to its 50% oxygen saturation) until Hct was 11%. P5K2 and P10K2 are PEG-conjugated hemoglobins that maintain most of the hemoglobin allosteric properties and have a cooperativity index of n = 2.2. The effects of these molecular solutions were compared with those obtained in a previous study using MP4, a PEG-modified hemoglobin whose P50 was 5.4 and cooperativity was 1.2 (Tsai et al., Am J Physiol Heart Circ Physiol 285:H1411-H1419, 2003). Tissue oxygen levels were higher after P5K2 (7.0 ± 2.5 mmHg) and P10K2 (6.3 ± 2.3 mmHg) versus MP4 (1.7 ± 0.5 mmHg) or the nonoxygen carrier Dextran 70 (1.3 ± 1.2 mmHg). Microvascular oxygen delivery was higher after P5K2 and P10K2 (2.22 and 2.34 ml O2/dl blood) compared with MP4 (1.41 ml O2/dl blood) or Dextran 70 (0.90 ml O2/dl blood); however, all these values were lower than control (7.42 ml O2/dl blood). The total hemoglobin in blood was similar in all cases; therefore, the improvement in tissue PO2 and oxygen delivery appears to be due to the increased cooperativity of the new molecules. [ABSTRACT FROM AUTHOR]

Published

2004

38. Microvascular pressure and functional capillary density in extreme hemodilution with low- and high-viscosity dextran and a low-viscosity Hb-based O2 carrier.

Author

Cabrales, Pedro, Tsai, Amy G., and Intaglietta, Marcos

Subjects

*HEMODILUTION, *CAPILLARIES, *DEXTRAN, *OXYGEN, *PERFUSION, *BLOOD pressure

Abstract

Blood losses are usually corrected initially by the restitution of volume with plasma expanders and subsequently by the restoration of oxygen-carrying capacity using either a blood transfusion or possibly, in the near future, oxygen-carrying plasma expanders. The present study was carried out to test the hypothesis that high-plasma viscosity hemodilution maintains perfused functional capillary density (FCD) by preserving capillary pressure. Microvascular pressure responses to extreme hemodilution with low- (LV) and high-viscosity (HV) plasma expanders and an exchange transfusion with a polymerized bovine cell-free Hb (PBH) solution were analyzed in the awake hamster window chamber model (n = 26). Systemic hematocrit was reduced from 50% to 11%. PBH produced a greater mean arterial blood pressure than the nonoxygen carders. FCD was higher after a HV plasma expander (70 ± 15%) vs. PBH (47 ± 12%). Microvascular pressure spanning the capillary network was higher after a HV plasma expander (16-19 mmHg) compared with PBH (12-16 mmHg) and a LV plasma expander (11-14 mmHg) but lower than control (22-26 mmHg). FCD was found to be directly proportional to capillary pressure. The use of a HV plasma expander in extreme hemodilution maintained the number of perfused capillaries and tissue perfusion by comparison with a LV plasma expander due to increased mean arterial blood pressure and capillary pressure. The use of PBH increased mean arterial pressure but reduced capillary pressure due to vasoconstriction and did not maintain FCD. [ABSTRACT FROM AUTHOR]

Published

2004

39. Oxygen delivery during extreme anemia with ultra-pure earthworm hemoglobin

Author

Elmer, Jacob, Palmer, Andre F., and Cabrales, Pedro

Subjects

*PHYSIOLOGICAL transport of oxygen, *ANEMIA treatment, *HEMOGLOBINS, *EARTHWORMS, *EXTRACELLULAR fluid, *OXIDATION, *PHYSIOLOGICAL effects of nitric oxide, *ERYTHROCYTES

Abstract

Abstract: Aim: Lumbricus terrestris (earthworm) erythrocruorin (LtEc) is a naturally occurring extracellular hemoglobin (Hb) with high molecular weight (3.6MDa), low autoxidation rate, and limited nitric oxide (NO) dioxygenation activity. These properties make LtEc a potential candidate for use as red blood cell (RBC) substitute, i.e. Hb-based oxygen carrier (HBOC). Previous studies have shown that small amounts of LtEc can be safely transfused into mice, rats, and hamsters without eliciting major side effects. Therefore, this study was designed to understand oxygen (O2) transport to tissues and systemic/microvascular hemodynamics induced by LtEc during anemic conditions. Main methods: Hamsters fitted with dorsal window chambers were hemodiluted to 18% hematocrit (Hct) using 6g/dL dextran 70kDa (Dex70). Hemodilution was then continued to 11% Hct using 10g/dL LtEc, 6g/dL Dex70 or 10g/dL human serum albumin (HSA). Blood pressure, heart rate, blood gas parameters, microvascular hemodynamics, microvascular blood flow, functional capillary density (FCD), intravascular pO2 and perivascular pO2 were studied. Key findings: LtEc maintained blood pressure without inducing vasoconstriction while increasing microvascular perfusion and FCD relative to Dex70 and HSA. LtEc increased blood O2 carrying capacity and maintained systemic and microvascular parameters without decreasing arteriolar diameter or increasing vascular resistance with during extreme anemia. LtEc increased O2 delivery compared to conventional plasma expanders. Significance: LtEc or synthetic molecules that replicate the characteristics of LtEc could be effective O2 carriers with potential to be used in transfusion medicine to prevent tissue anoxia resulting from severe anemia. [Copyright &y& Elsevier]

Published

2012

40. Perfusion vs. oxygen delivery in transfusion with “fresh” and “old” red blood cells: The experimental evidence

Author

Tsai, Amy G., Hofmann, Axel, Cabrales, Pedro, and Intaglietta, Marcos

Subjects

*BLOOD transfusion, *PERFUSION, *PHYSIOLOGICAL transport of oxygen, *ERYTHROCYTES, *HEMODILUTION, *HEMORRHAGIC shock

Abstract

Abstract: We review the experimental evidence showing systemic and microvascular effects of blood transfusions instituted to support the organism in extreme hemodilution and hemorrhagic shock, focusing on the use of fresh vs. stored blood as a variable. The question: “What does a blood transfusion remedy?” was analyzed in experimental models addressing systemic and microvascular effects showing that oxygen delivery is not the only function that must be addressed. In extreme hemodilution and hemorrhagic shock blood transfusions simultaneously restore blood viscosity and oxygen carrying capacity, the former being critically needed for re-establishing a functional mechanical environment of the microcirculation, necessary for obtaining adequate capillary blood perfusion. Increased oxygen affinity due to 2,3 DPG depletion is shown to have either no effect or a positive oxygenation effect, when the transfused red blood cells (RBCs) do not cause additional flow impairment due to structural malfunctions including increased rigidity and release of hemoglobin. It is concluded that fresh RBCs are shown to be superior to stored RBCs in transfusion, however increased oxygen affinity may be a positive factor in hemorrhagic shock resuscitation. Although experimental studies seldom reproduce emergency and clinical conditions, nonetheless they serve to explore fundamental physiological mechanisms in the microcirculation that cannot be directly studied in humans. [ABSTRACT FROM AUTHOR]

Published

2010